KR102612378B1 - secondary battery material extraction system - Google Patents

Abstract

The present invention relates to a secondary battery raw material extraction system with a new structure that can effectively extract and recover black powder generated from waste secondary batteries.
In the secondary battery raw material extraction system according to the present invention, when the primary shredder (20) crushes the waste secondary batteries supplied by the supply conveyor device (10) and discharges the pulverized material, the discharged pulverized material is sent to the primary cyclone device. After passing through (30), it passes through the first vibration separator (40) and the pulverized material is sorted into black powder and other materials and discharged.
In addition, other substances discharged from the primary vibration separator (40) pass through the secondary crusher (50) to be pulverized into smaller pieces, and then pass through the secondary cyclone device (60) and the secondary vibration separator (70) to form other substances. The black powder contained in is selected again.
Therefore, there is an advantage in that the black powder contained in the waste secondary battery can be selected effectively by selecting the black powder in two stages.

Description

Secondary battery material extraction system

The present invention relates to a secondary battery raw material extraction system with a new structure that can effectively extract and recover black powder generated from waste secondary batteries.

Recently, the use of electric vehicles has rapidly increased, and accordingly, a large amount of waste secondary batteries used in electric vehicles have been generated.

In addition, when disposing of secondary batteries, a large amount of black powder, that is, powder containing nickel, chromium, cobalt, and graphite, is generated, and methods for recovering such black powder are being developed.

However, there has been a problem that a method for effectively recovering black powder from these secondary batteries has not been developed so far.

Therefore, a new method to solve these problems has become necessary.

Registered Patent No. 10-2252019,

The present invention is intended to solve the above problems, and its purpose is to provide a secondary battery raw material extraction system with a new structure that can effectively extract and recover black powder generated from waste secondary batteries.

The present invention for achieving the above object includes a supply conveyor device 10 for transporting waste secondary batteries, and a primary shredder 20 for crushing waste secondary batteries supplied by the supply conveyor device 10. and a primary cyclone device (30) that removes dust from the pulverized material discharged from the primary crusher (20), and is provided on the lower side of the primary cyclone device (30) and discharged from the primary cyclone device (30). A primary vibration separator (40) that separates and discharges the pulverized material into black powder and other substances, a secondary crusher (50) that crushes other substances discharged from the primary vibration separator (40), and the secondary crusher (50) A secondary cyclone device (60) that removes dust contained in other materials discharged from the crusher (50), and other materials discharged from the secondary cyclone device (60), which are provided below the secondary cyclone device (60). A secondary vibration separator (70) that separates and discharges black powder and other substances, and is connected to the secondary cyclone device (60) to select black powder contained in the dust discharged from the secondary cyclone device (60). A secondary battery raw material extraction system is provided, comprising a tertiary cyclone device (80).

According to another feature of the present invention, it further includes a sorting device (90) connected to the secondary vibration sorter (70) to select metal components from other substances discharged from the secondary vibration sorter (70), and the sorting device (90) includes a support frame 91, a sorting case 92 provided on the support frame 91 and having front and rear outlets 92a and 92b at the front and rear, and a vibration means provided on the support frame 91 ( 93), and a sorting unit provided to be inclined forward and downward on the upper surface of the vibrating means 93 so as to be located inside the sorting case 92, and other materials discharged from the secondary vibrating sorter 70 are supplied to the upper surface. A plate 94 and the support frame 91 are provided on the upper part of the sorting plate 94 to face backwards, so that air is blown backwards on the upper surface of the sorting plate 94, thereby forming the upper part of the sorting plate 94. It includes an air supply means (95) for classifying other materials supplied to the device according to their specific gravity. A through hole (92c) is formed on the lower side of the selection case (92), and the front and rear ends of the selection plate (94) are It extends to the front and rear of the sorting case 92 through the front and rear outlets 92a and 92b, and the vibrating means 93 includes a support 93a fixed to the support frame 91 and an upper side of the support 93a. A plurality of elastic plates 93b are provided to extend into the inside of the sorting case 92 through the through hole 92c, and are provided to face each other on the front surfaces of the support 93a and the elastic plate 93b. Power applied to the first and second electromagnets (93c, 93d), including the first and second electromagnets (93c, 93d) and the diaphragm (93e) fixed to the top of the elastic plate (93b) It is configured to control and vibrate the elastic plate (93b) and the vibration plate (93e) in the forward and backward directions at high speed. A plurality of the elastic plates (93b) are provided to be spaced apart from each other in the forward and backward directions so that the upper ends vibrate in the forward and backward directions. Constructed, the second electromagnet (93d) is provided to face the first electromagnet (93c) on the front of the elastic plate (93b) located at the front, and the selection plate (94) is located on the upper surface of the vibration plate (93e). It is fixed to, and the air supply means 95 includes a plurality of support panels 95a provided inside the selection case 92 to be spaced apart from each other in the front and rear directions, and a rearward facing surface of the support panel 95a. A plurality of injection nozzles 95b provided to do so, an air compressor 95d connected to the injection nozzle 95b through an air supply pipe 95c, and a pressure regulator 95e provided in the middle of the air supply pipe 95c. ), a secondary battery raw material extraction system is provided, characterized in that the pressure of the air injected backward through the injection nozzle (95b) can be adjusted by manipulating the pressure regulator (95e).

According to another feature of the present invention, a supply hole 92d to which the second vibration separator is connected is formed in the middle portion of the upper surface of the sorting case 92, and an auxiliary cyclone device 99 is installed at the front and rear of the upper surface of the sorting case 92. ) is connected to the suction hole (92e), and other materials that have passed through the second vibrating separator are supplied to the upper surface of the sorting plate (94) through the supply hole (92d), and the sorting plate (94) is vibrated. A secondary battery raw material extraction system is provided, wherein the dust generated accordingly is supplied to the second cyclone device through the suction hole (92e).

According to another feature of the present invention, first and second cameras 96 and 97 are provided at the front and rear of the sorting case 92, respectively, to photograph other substances discharged from the front and rear ends of the sorting plate 94; By analyzing the images from the first and second cameras 96 and 97, the size or composition of other substances discharged from the front and rear ends of the selection plate 94 are analyzed, and the analysis means 98 controls the pressure regulator 95e. ) further includes, and the analysis means 98 controls the pressure regulator 95e according to the results derived by analyzing the images captured by the first and second cameras 96 and 97 to control the air supply means ( A secondary battery raw material extraction system is provided, characterized in that it adjusts the pressure of air sprayed onto the upper part of the selection plate 94 through 95).

In the secondary battery raw material extraction system according to the present invention, when the primary shredder (20) crushes the waste secondary batteries supplied by the supply conveyor device (10) and discharges the pulverized material, the discharged pulverized material is sent to the primary cyclone device. After passing through (30), it passes through the first vibration separator (40) and the pulverized material is sorted into black powder and other materials and discharged.

In addition, other substances discharged from the primary vibration separator (40) pass through the secondary crusher (50) to be pulverized into smaller pieces, and then pass through the secondary cyclone device (60) and the secondary vibration separator (70) to form other substances. The black powder contained in is selected again.

Therefore, there is an advantage in that the black powder contained in the waste secondary battery can be selected effectively by selecting the black powder in two stages.

1 is a configuration diagram showing a secondary battery raw material extraction system according to the present invention;
Figure 2 is a side cross-sectional view showing the vibrating screen device of the secondary battery raw material extraction system according to the present invention;
Figure 3 is a configuration diagram showing a sorting device of the second embodiment of the secondary battery raw material extraction system according to the present invention;
Figure 4 is a side cross-sectional view showing the sorting device of the second embodiment of the secondary battery raw material extraction system according to the present invention;
Figure 5 is a block diagram of the sorting device of the second embodiment of the secondary battery raw material extraction system according to the present invention;
Figure 6 is a side cross-sectional view showing the operation of the sorting device of the second embodiment of the secondary battery raw material extraction system according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached illustration drawings.

1 and 2 illustrate a secondary battery raw material extraction system according to the present invention, which includes a supply conveyor device 10 for transporting waste secondary batteries, and waste secondary batteries supplied by the supply conveyor device 10. A primary shredder (20) for pulverizing the battery, a primary cyclone device (30) connected to the primary shredder (20), and a primary cyclone device (30) provided below the primary cyclone device (30). A primary vibration separator (40) for separating and discharging the pulverized material discharged from the black powder and other materials, a secondary pulverizer (50) for pulverizing the other materials discharged from the primary vibration separator (40), and 2 above. A secondary cyclone device (60) that removes dust contained in other substances discharged from the secondary crusher (50), and other substances discharged from the secondary cyclone device (60) and provided below the secondary cyclone device (60). A secondary vibration separator (70) that separates materials into black powder and other materials and discharges them, and is connected to the secondary cyclone device (60) to select black powder contained in the dust discharged from the secondary cyclone device (60). It consists of a tertiary cyclone device (80) that

The primary crusher 20 uses a general hammer mill.

The primary cyclone device 30 is connected to the primary pulverizer 20 through a supply pipe, removes dust contained in the pulverized material discharged from the primary pulverizer 20, and grinds the dust from which the dust has been removed. Discharge water to the bottom.

As shown in FIG. 2, the primary vibration separator 40 is provided with a screen 42 inside the main body 41 and a vibration means 43 for vibrating the screen 42, so that the primary When the pulverized material discharged from the lower side of the cyclone device 30 is supplied to the upper part of the screen 42, other materials larger than the standard are discharged to the circumference of the main body 41 and supplied to the secondary crusher 50. , small-sized black powder passes through the screen 42 and is discharged to the lower side to be collected in a collection container (not shown) provided at the lower side.

At this time, the primary vibration separator (40) is composed of two pieces, and divides and processes the pulverized material discharged from the primary cyclone device (30).

The secondary crusher 50 uses a cutter mill that crushes and discharges other materials discharged from the periphery of the primary vibration separator 40 into smaller pieces.

The secondary cyclone device (60) is connected to the secondary crusher (50) through a supply pipe and removes dust contained in other materials discharged from the secondary crusher (50), discharging the dust to the upper side, and other materials to the lower side. discharged as

The secondary vibration separator 70 is configured in the same way as the primary vibration separator 40, and discharges black powder contained in other materials to the lower side, and discharges other materials from which the black powder has been removed to the peripheral portion.

The tertiary cyclone device 80 is connected to the top of the secondary cyclone device 60, and selects and collects black powder contained in the dust discharged from the top of the secondary cyclone device 60.

Since the above-described first to third cyclone devices 80 are generally used, further detailed description thereof will be omitted.

In the secondary battery raw material extraction system configured in this way, when the primary shredder 20 crushes the waste secondary batteries supplied by the supply conveyor device 10 and discharges the pulverized material, the discharged pulverized material is sent to the primary cyclone device ( After passing through 30), it passes through the first vibration separator 40 and the pulverized material is sorted into black powder and other substances and discharged.

In addition, other substances discharged from the primary vibration separator (40) pass through the secondary crusher (50) to be pulverized into smaller pieces, and then pass through the secondary cyclone device (60) and the secondary vibration separator (70) to form other substances. The black powder contained in is selected again.

Therefore, there is an advantage in that the black powder contained in the waste secondary battery can be selected effectively by selecting the black powder in two stages.

In addition, the tertiary cyclone device 80 connected to the secondary cyclone device 60 is used to select a small amount of black powder contained in the dust filtered by the secondary cyclone device 60, so that the black powder is not selected. It has the advantage of preventing discharge.

3 to 6 show a second embodiment according to the present invention, which is a screening device connected to the secondary vibration separator 70 to separate metal components from other substances discharged from the secondary vibration separator 70. (90) is further provided.

The sorting device 90 includes a support frame 91, a sorting case 92 provided on the support frame 91 and having front and rear outlets 92a and 92b at the front and rear, and a support frame 91. A vibrating means (93) and a sorting device provided to be inclined forward and downward on the upper surface of the vibrating means (93) so as to be located inside the sorting case (92), and other materials discharged from the second vibrating sorter are supplied to the upper surface. A plate 94 and the support frame 91 are provided on the upper part of the sorting plate 94 to face backwards, so that air is blown backwards on the upper surface of the sorting plate 94, thereby forming the upper part of the sorting plate 94. an air supply means (95) for classifying other materials supplied to the device according to their specific gravity, and first and The second camera (96,97) and the images of the first and second cameras (96,97) are analyzed to analyze the size or composition of other substances discharged from the front and rear ends of the selection plate (94), and the pressure regulator It consists of analysis means 98 that controls (95e).

The selection case 92 is configured in a box shape extending in the front-back direction and is fixed to the upper surface of the support frame 91. A plurality of through-holes 92c are formed on the lower side to be spaced at regular intervals in the front-back direction. .

At this time, a supply hole (92d) connected to the second vibration separator is formed in the middle portion of the upper surface of the sorting case 92, and a suction hole to which an auxiliary cyclone device 99 is connected is formed at the front and rear of the upper surface of the sorting case 92. (92e) is formed, and other substances discharged to the periphery of the second vibrating separator are supplied to the upper surface of the sorting plate (94) through the supply hole (92d).

The vibrating means 93 includes a support 93a fixed to the support frame 91, and extends upward from the support 93a to extend into the inside of the sorting case 92 through the through hole 92c. A plurality of elastic plates (93b) provided, first and second electromagnets (93c, 93d) provided to face each other on the front surface of the support (93a) and the elastic plate (93b), and the elastic plate (93b) It consists of a vibration plate (93e) fixed at the top.

The elastic plate 93b is composed of a rectangular plate shape made of highly elastic metal that is long in the vertical direction and narrow in the lateral direction. The lower end is fixed to the support 93a so as to be spaced apart in the forward and backward directions, and the upper end is the vibration plate. It is fixed to the lower side of 93e and supports the diaphragm 93e so that it vibrates at high speed in the front-back direction.

The first electromagnet 93c is fixed to the rear side of the support block provided on the upper surface of the support 93a, and the second electromagnet 93d is fixed to the front of the elastic plate 93b located at the frontmost position. It is provided to face the first electromagnet (93c), and controls the power applied to the first and second electromagnets (93c, 93d) so that the first and second electromagnets (93c, 93d) are connected to the same electrode or to different electrodes. When charged, the first electromagnet 93c and the second electromagnet 93d attract or repel each other.

The vibration plate 93e is provided to extend in the front-back direction inside the sorting case 92 and is fixed to the top of the elastic plate 93b.

Therefore, when the power applied to the first and second electromagnets 93c and 93d is controlled to cause the elastic plate 93b to elastically deform in the front and rear directions at high speed, the diaphragm provided at the top of the elastic plate 93b (93e) is vibrated back and forth at high speed.

The sorting plate 94 is composed of a bottom plate 94a and a side plate 94b extending upward from both sides of the bottom plate 94a and is fixed to the upper surface of the diaphragm 93e, and the front and rear ends are It extends to the front and rear of the sorting case (92) through the front and rear outlets (92a, 92b).

The air supply means 95 includes a plurality of support panels 95a provided inside the selection case 92 to be spaced apart from each other in the front and rear direction, and a plurality of support panels 95a provided on the rear side of the support panel 95a to face rearward. It consists of four injection nozzles (95b), an air compressor (95d) connected to the injection nozzles (95b) through an air supply pipe (95c), and a pressure regulator (95e) provided in the middle of the air supply pipe (95c). .

A plurality of spray nozzles 95b are provided on the support panel 95a to be spaced apart from each other in the lateral direction, and spray high-pressure air supplied through the air supply pipe 95c onto the entire upper surface of the selection plate 94. It is configured to do so.

The pressure regulator 95e uses an electronic pressure regulator 95e controlled according to the control of the analysis means 98, and controls the pressure of air supplied to the injection nozzle 95b through the air supply pipe 95c. By doing so, the pressure of air sprayed backward through the spray nozzle 95b is adjusted.

Therefore, as shown in FIG. 6, in a state in which the vibrating means 93 is driven to vibrate the sorting plate 94 in the forward and backward directions, other substances discharged from the secondary vibrating sorter 70 are supplied. When supplied to the upper part of the sorting plate 94 through the ball 92d, other materials slowly move forward while vibrating in the up and down direction due to the inclination and vibration of the sorting plate 94.

At this time, when the air supply means 95 is driven to spray air backwards on the upper part of the sorting plate 94, wastes such as plastics with a small specific gravity among other materials supplied to the upper surface of the sorting plate 94 are blown into the air. It is pushed backward and finally discharged to the rear of the sorting plate 94, and the metal material with a large specific gravity is discharged to the front of the sorting plate 94.

Therefore, waste and metal materials discharged from the front and rear ends of the sorting plate 94 can be collected using the collection bins 1 provided at the front and rear of the sorting device 90.

That is, other materials discharged from the second vibration separator and supplied to the sorting plate 94 are a mixture of heavy metal materials and light waste such as synthetic resin.

At this time, if the pressure of the air supplied to the spray nozzle 95b is strongly adjusted by manipulating the pressure regulator 95e, light metal materials with a large specific gravity are discharged to the rear together with the waste, and if the air pressure is adjusted weakly, the waste is discharged backward. Since the heavy metal material is discharged to the front along with the metal material, the pressure of the air supplied to the spray nozzle (95b) is controlled by adjusting the pressure regulator (95e), so the heavy metal material is discharged to the front end of the selection plate (94). And light waste can be precisely controlled to be discharged to the rear end of the sorting plate (94).

The first and second cameras 96, 97 are provided on the upper front and rear ends of the sorting plate 94, and capture metal substances and waste discharged from the front and rear ends of the sorting plate 94 in real time. It is configured to transmit to (98).

The analysis means 98 analyzes the images captured by the first and second cameras 96 and 97 to analyze the ratio of metal materials and waste discharged to the front of the selection plate 94, and the analyzed results Accordingly, by controlling the pressure regulator 95e to adjust the pressure of the air sprayed onto the upper part of the sorting plate 94 through the spray nozzle 95b, the metal material can be recycled to the front of the sorting plate 94. Only the metal material is discharged, and as little metal material as possible is discharged to the rear of the selection plate 94.

In this way, various hardware or program methods have been developed and used to analyze the ratio of metal substances or other substances by analyzing the images captured by the cameras 96 and 97, so further detailed descriptions thereof are omitted. do.

The secondary battery raw material extraction system configured in this way uses the sorting device 90 to select metal materials and waste from other materials discharged from the secondary vibration sorter 70 according to specific gravity, thereby increasing the recycling rate of waste secondary batteries. There are advantages that can be improved.

In addition, the images captured by the first and second cameras 96 and 97 are analyzed using the analysis means 98, and the pressure regulator 95e is controlled according to the results, thereby removing metal substances and waste. It has the advantage of being able to select more precisely.

10. Supply conveyor device 20. Primary crusher
30. Primary cyclone device 40. Primary sorter
50. Secondary crusher 60. Secondary cyclone device
70. Secondary sorter 80. Tertiary cyclone device

Claims (3)

A supply conveyor device (10) for transporting waste secondary batteries,
A primary shredder (20) for shredding the waste secondary batteries supplied by the supply conveyor device (10);
A primary cyclone device (30) for removing dust from the pulverized material discharged from the primary pulverizer (20);
A primary vibration separator (40) is provided below the primary cyclone device (30) and separates the pulverized material discharged from the primary cyclone device (30) into black powder and other substances and discharges them;
A secondary crusher (50) that crushes other substances discharged from the first vibration separator (40),
A secondary cyclone device (60) for removing dust contained in other materials discharged from the secondary crusher (50),
A secondary vibration separator (70) provided below the secondary cyclone device (60) and separating other materials discharged from the secondary cyclone device (60) into black powder and other materials and discharging them;
A tertiary cyclone device (80) connected to the secondary cyclone device (60) to select black powder contained in the dust discharged from the secondary cyclone device (60);
It includes a screening device (90) connected to the secondary vibration separator (70) to select metal components from other substances discharged from the secondary vibration separator (70),
The sorting device 90 is
A support frame (91),
A sorting case (92) provided on the support frame (91) and having front and rear outlets (92a, 92b) at the front and rear,
Vibration means 93 provided on the support frame 91,
A sorting plate 94 is provided so as to be tilted forward and downward on the upper surface of the vibrating means 93 so as to be located inside the sorting case 92, and other substances discharged from the secondary vibrating sorter 70 are supplied to the upper surface. class,
It is provided on the support frame 91 to face backwards on the upper part of the sorting plate 94, and blows air backwards on the upper surface of the sorting plate 94 to remove other materials supplied to the upper part of the sorting plate 94. It includes an air supply means (95) classified according to specific gravity,
A through hole 92c is formed on the lower side of the selection case 92,
The front and rear ends of the sorting plate 94 extend to the front and rear of the sorting case 92 through the front and rear outlets 92a and 92b,
The vibration means (93) is
A support bar (93a) fixed to the support frame (91),
a plurality of elastic plates (93b) extending upward from the support (93a) and extending into the interior of the sorting case (92) through the through hole (92c);
First and second electromagnets (93c, 93d) provided to face each other on the front surfaces of the support (93a) and the elastic plate (93b),
Including a vibration plate (93e) fixed to the top of the elastic plate (93b),
It is configured to control the power applied to the first and second electromagnets (93c, 93d) to vibrate the elastic plate (93b) and the diaphragm plate (93e) in the forward and backward directions at high speed,
A plurality of the elastic plates 93b are provided to be spaced apart from each other in the front-back direction and the upper end is configured to vibrate in the front-back direction,
The second electromagnet (93d) is provided to face the first electromagnet (93c) on the front side of the frontmost elastic plate (93b),
The selection plate 94 is fixed to the upper surface of the vibration plate 93e,
The air supply means (95) is
A plurality of support panels (95a) provided inside the selection case (92) to be spaced apart from each other in the front and rear directions,
A plurality of injection nozzles (95b) provided on the rear side of the support panel (95a) to face rearward, and an air compressor (95d) connected to the injection nozzles (95b) through an air supply pipe (95c),
Including a pressure regulator (95e) provided in the middle of the air supply pipe (95c),
A secondary battery raw material extraction system, characterized in that the pressure of air sprayed backward through the spray nozzle (95b) can be adjusted by manipulating the pressure regulator (95e).
According to clause 1,
First and second cameras (96, 97) respectively provided at the front and rear of the sorting case (92) to photograph other substances discharged from the front and rear ends of the sorting plate (94);
By analyzing the images from the first and second cameras 96 and 97, the size or composition of other substances discharged from the front and rear ends of the selection plate 94 are analyzed, and the analysis means 98 controls the pressure regulator 95e. ) further includes,
The analysis means 98 analyzes the images captured by the first and second cameras 96 and 97 and controls the pressure regulator 95e according to the results derived from the selection plate through the air supply means 95. A secondary battery raw material extraction system characterized in that it is designed to control the pressure of the air injected into the upper part of (94). delete

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